DE19943456A1 - Telemetric system for monitoring ovulation in women comprises one or more sensors and transmitting unit embedded in flexible, annular pessary - Google Patents

Abstract

Telemetric system for monitoring ovulation in women comprises one or more sensors (2) and a transmitting unit (3). These are embedded in a flexible, annular pessary (1).

Description

Field of application of the invention

The invention relates to an arrangement for ovulation monitoring according to the preamble of claim 1.

State of the art

Reproductive ability is an important aspect of the health of a larger one Population group. It is influenced by a variety of physiological factors as well as by physi calic and chemical environmental parameters. The increasing influence of Environmental factors and knowledge of the resulting risks lead to an increase the need for methods by which the reproductive ability of the population is assessed can be made without the living conditions of subjects by using the methods to influence significantly. Reproduction Toxicology (1990), No. 4, page 1-2 refers to the lack of availability of methods for reproductive screening in women grasslands. Measuring methods by which the menstrual cycle and fertility without intervention in the daily routine of the women to be examined can become urgent needed.

So far, the course of the menstrual cycle of women under normal environment conditions based on secondary parameters, primarily body core temperature, documented. The post-ovulatory temperature increase is always around 0.5 ° C evaluated. DE 32 23 657 and DE 195 24 966 describe methods for temperature measurement, Storage of the measured values obtained and evaluation with a wrist carrying device described. In the utility model G 92 15 558.8 there is a device for measuring the temperature in the vaginal canal with telemetric transmission of the measurement data to an external storage medium. Procedures with which the basal Temperature determined in the vaginal canal and wire transfer in an external memory is filed, the patents EP 0667118 and DE 32 11 573 can be found.

As the course of the basal body temperature shows circadian fluctuations and with a large number experience of women from other factors such as physical activity can be influenced that the assessment of the menstrual cycle is faulty, are increasingly becoming other, characteristic of the menstrual cycle Parameters determined. As a prospectus from Unipath Diagnostics GmbH, Cologne can be seen, the concentration of the Luteinizing hormone (LH) measured in urine and core body temperature recorded to detect ovulation.

US 5209238 describes a multiple sensor for ovulation monitoring, which is described in the vaginal canal is introduced and online measurements of the LH concentration and the pH in the vaginal secretion, the density of the vaginal secretion and the basal body temperature in the Vaginal canal. This cylindrical sensor is with optical and acoustic Signalers are equipped to display ovulation and can be used both for fertility treatment as well as to prevent pregnancy.

In US 4753247 the measurement of the redox potential for predicting ovulation is pre- beat. Another measurement method for detecting ovulation exists according to US 4498481 in the detection of the electrical conductivity of the vaginal secretion.  

Obstetrics and gynecology 57 (1997), pages 549-554, describe a monitoring method that enables ovulation detection based on the course of the end-expiratory CO ₂ partial pressure, since the CO ₂ partial pressure determined in the breathing gas drops significantly before the ovulation.

Criticism of the state of the art

The previously known measurement methods for assessing the menstrual cycle each have certain advantages and disadvantages with regard to applicability and reliability. Measurement methods that detect ovulation from body temperature, measured on the arm or in the armpit, because of the disturbing influence of the environment temperature a relatively low reliability. By measuring the core body temperature In principle, these disorders are avoided in the vaginal canal.

The circadian fluctuations in the core body temperature can be up to ± 0.5 ° C. That is why the measurement of the body core temperature is used to identify the ovulation-related Always increase the temperature by about 0.5 ° C in the morning after waking up. Many years of experience show that patients with an irregular daily routine reliable detection of the basal temperature increase during ovulation with this Measurement method is not possible.

The additional evaluation of other secondary parameters such as LH concentration, pH value, density and conductivity of the vaginal secretion as well as pCO ₂ measurement in breathing gas can improve the safety of ovulation detection and the assessment of the fertilization capacity of the egg cell, as in one in Reproductive Toxicology 6 (1992), pages 385-400. However, these methods are too expensive for broad screening. In addition, they can usually not be carried out by the participating test subjects themselves, so that they can only be made possible by frequent visits to the doctor.

In addition to the costs and costs required for a reproduction screening A high level of reliability is another important problem area in the impairment the living conditions of the test subjects. On the one hand, the physical tolerance of the applied measurement methods should be guaranteed, on the other hand, the time required for the Measurements as well as changes in the daily routine of the subjects as a result be kept low.

Measuring devices that are inserted into the vaginal canal (described in US 5209238 and G 9215558.8) and seal them with their shape and size are for one long unsuitable for time use because the flow of secretions in the vaginal canal is impeded. Even with one Short-term use reduce devices with a rigid housing and / or riding a larger one Weight the comfort. Measurement methods based on discontinuously determined values in the Urine or inhaled air can fall through if trained by untrained personnel be guided, be flawed. You are also liable for the lack that the measuring inter valle cannot be chosen arbitrarily small. In addition, the extensive use leads laboratory diagnostic methods required for measurements in the urine Costs.

task

The invention is based on the object, the deficiencies of the prior art to eliminate, in particular a device for ovulation monitoring in women realize that both in individual cases and in large-scale studies, a reliable assessment division of the menstrual cycle inexpensively without significant impairment to the Subjects is guaranteed.

Description of the invention

The basic idea of the present invention is to use sensors for characteristic embed parameters that characterize ovulation in a flexible ring pessary and the ring Place the pessary in the vaginal canal in front of the cervix. Parameters of special importance activity are: core body temperature and pH. The arrangement according to the invention is not limited to these parameters, but can also be more, especially chemical and bio concern chemical parameters that can be measured by sensors.

To ensure the unrestricted mobility of the test subjects, the sensors signals on line using telemetric data transmission from the ring pessary to one external receiver unit to be worn on the body and temporarily stored there. The data can be read out from the buffer and at freely selectable intervals be evaluated for the purpose of cycle monitoring. The external receiving unit can continue to be carried out in such a way that data evaluation with optical or acoustic Impending ovulation is signaled.

Embodiments

The invention will become more apparent in the following description and with reference to the drawings explained. Show it:

Fig. 1 shows an embodiment of the telemetric sensor system according to the invention for ovulation monitoring, embedded in a flexible ring pessary and

Fig. 2 shows an embodiment of the receiving unit according to the invention with reading terminal and optical or acoustic signaling of an impending ovulation.

Fig. 3 shows a second embodiment of the telemetric sensor system according to the invention

Description of the embodiments

In Fig. 1, an embodiment for the flexible ring pessary 1 is shown, which holds a sensor 2 for measuring the body core temperature and a telemetric transmission unit 3 ent. All components are liquid-tight embedded in the flexible ring pessary. The temperature sensor converts the current values of the body core temperature into an electrical resistance. This resistance value is converted in the transmitter unit and sent telemetrically to an external receiver unit. The transmission between the transmitter unit in the ring pessary and the external receiver unit is done inductively. The range of the transmitting unit is set so that the transmission to the receiving unit arranged on the body surface in the region of the belt line is ensured under all occurring environmental conditions.

The flexible ring pessary is made of a body-compatible silicone by an outer cover 4 rubber and an inner ring core 5, which is made of an elastomer that has a very low water vapor permeability. The telemetric broadcast unit and the temperature sensor are embedded in the toroid 5. The ring pessary also contains a primary cell 6 for supplying power to the telemetric transmission unit. The transmitter unit has a low energy consumption, so that the Ring pessaries over six months is ensured. To automatically switch on the To ensure ring pessaries during commissioning, a switch 7 is in the elastomer ring 5 embedded, the z. B. by an external magnetic field (reed contact) or by lowering the Outside temperature (bimetallic switch) is actuated and the transmitter unit is switched off causes. The connecting lines 8 are flexible, so that they are compressed of the ring pessary when inserting into the vaginal canal to ensure that the contacts are not interrupted can lead.

Fig. 2 shows the external receiving unit 9 of the telemetischen monitoring system. It should be worn in the immediate vicinity of the body surface at the level of the belt line. The receiving unit contains a coil 10 as part of an oscillating circuit for receiving the sensor signals. The signals are processed in an electronic unit 11 and evaluated and stored by a micro processor 12 with memory 13. Through the interface 14, the data can be read out at any time interval and made available to the attending physician for fertility treatment or a study through existing communication networks. The receiving unit also contains an optical display 15, for example in the form of a light-emitting diode, and an acoustic signal generator 16, for example in the form of a piezo transducer, for predicting ovulation.

Due to a high integration density of the electronic components used, the Receiver unit can be miniaturized so that the outer dimensions are less than (100 × 60 × 10) mm. The receiving unit also contains one or more primary or secondary cells 17 and an inductive or thermal switch 18, the auto Automatic commissioning of the receiving unit guaranteed. An optimized energy consumption enables the receiver unit to be used without interruption for more than 6 months. The housing of the receiving unit is watertight, so that the Receiver unit can also be worn when bathing.

Fig. 3 shows a second embodiment of the flexible ring pessary. In addition to the components listed in the first exemplary embodiment, the ring pessary contains a pH sensor 19 which converts the pH value in the vaginal secretion into a potential value.

The sensitive surface 20 of the pH sensor is on the outer surface of the ring pessary arranged so that direct contact of the sensitive surface with the vaginal secretion given is. The potential value corresponding to the pH value becomes just like the value for the Body core temperature telemetrically transmitted to the receiving unit 9 and stored there.

Advantages of the invention

By continuously measuring the body's core temperature over a longer period of time is the detection of upcoming ovulations and the assessment of fertility in women possible over a long period of time with previously unattainable security. Because the data can be read out at any time via the interface and then evaluated, is one high diagnostic reliability.

The flexible ring pessary with the embedded temperature sensor or with several sensors can easily be inserted into the vaginal canal and over a period of more than  100 days can be used for measurement. From the use of the usual flexible ring Pessaries for hormone dosing are known to have no adverse effects on life leadership of the wearer and have excellent long-term tolerance. For the inductive telemetric transmission of the sensor-determined values for reception unit with a short range requires a low transmission power (P <10 µW). The Inductive transmission is due to high immunity to electromagnetic interference Interferences from the surrounding area are marked.

Thanks to the waterproof miniaturized version, it is also suitable for the receiver unit high wearing comfort guaranteed. The program-guided, automated reading of the stored signals leads to a high level of operational security, so that the data of everyone Users can be read out without a doctor's visit and forwarded or evaluated.  

Lists of reference numbers

1

flexible ring pessary

2nd

Sensor for measuring body core temperature

3rd

telemetric transmission unit

4th

outer shell of the ring pessary made of body-compatible silicone rubber

5

inner core of the ring pessary made of a water vapor impermeable elastomer

6

Primary cell for the voltage supply of the transmitter unit

7

inductive or thermal switch for automatic commissioning of the ring

8th

flexible connecting lines in the pessary

9

external receiving unit

10th

Receiving coil

11

electronic unit for data processing

12th

microprocessor

13

Data storage

14

Interface for digital data transmission

15

optical display

16

acoustic signal generator

17th

Primary or secondary cells for the power supply of the receiving unit

18th

inductive or thermal switch for automatic commissioning of the receiver unit

19th

pH sensor

20th

sensitive area of the pH sensor

Claims (13)

1.Telemetric measuring system for ovulation monitoring in women, consisting of a transmitter unit with one or more sensors for measuring parameters characteristic of ovulation in the vaginal canal and a receiver unit for storing the measurement data, characterized in that the sensor or the sensors and the transmitter unit in a flexible Ring pessary (1) are embedded. 2. Device according to claim 1, characterized in that the ring pessary is a sensor contains for measuring the body core temperature. 3. Device according to claim 1, characterized in that the ring pessary is a sensor for measuring the pH value in vaginal secretions. 4. The device according to claim 1, characterized in that the ring pessary one Temperature sensor for measuring body core temperature and a pH sensor for measurement contains the pH value in the vaginal secretions. 5. Device according to claims 1 to 4, characterized in that the ring pessary contains further sensors for measuring parameters characteristic of ovulation. 6. Device according to claims 1 to 5, characterized in that the ring pessary contains an inductive switch that the transmitter unit in the ring pessary in the absence of an outside magnetic field automatically turns on. 7. Device according to claims 1 to 6, characterized in that the ring pessary an outer shell made of a body-compatible silicone rubber and an inner ring a water vapor impermeable elastomer. 8. Device according to claims 1 to 7, characterized in that the Sensor signals are transmitted inductively to an external receiving device (9) on line and in the Receiver unit can be saved. 9. Device according to claims 1 to 8, characterized in that the reception digital evaluation electronics for processing the measurement data for the purpose of Includes detection of an upcoming ovulation. 10. Device according to claims 1 to 9, characterized in that the external Receiver unit is worn on the body at the level of the belt line. 11. The device according to claims 1 to 10, characterized in that the external Receiving unit contains an inductive switch that the receiving unit in the absence of a external magnetic field turns on automatically. 12. The device according to claims 1 to 11, characterized in that the Receiving unit an optical and / or acoustic signaling of an upcoming Contains ovulation. 13. Device according to claims 1 to 12, characterized in that the Receiving unit contains an interface for digital reading of the measurement data.